Analyzer, and method for performing a measurement on a sample

ABSTRACT

An analyzer includes a display, measurement hardware configured to perform a measurement on a sample, and a controller. The controller is in communication with the display and the measurement hardware and is configured to communicate, via the display, a first pre-analytical procedure of the sample prior to measurement of the sample. The controller is also configured to maintain the analyzer in a state associated with the first procedure for an amount of time equal to a time needed for performing the first procedure. After the time needed for performing the first procedure has elapsed, the controller is configured to communicate, via the display, a second pre-analytical procedure of the sample prior to measurement of the sample.

BACKGROUND

i) Field

This application relates to an analyzer and its components. Inparticular, this application relates to a clinical analyzer and systemconfigured to ensure that an operator is qualified to use the analyzerand that the operator adheres to certain procedures while operating theanalyzer.

ii) Description of the Related Art

Hematology analyzers are utilized to make various measurements of theconstituents of a blood sample. Many known hematology analyzers arelarge cumbersome machines placed in hospitals and laboratories. Suchanalyzers are required to be operated by an operator officiallycertified to operate the analyzers.

Smaller hematology analyzers, such as the analyzers described in U.S.Pat. Nos. 6,772,650 and 7,013,260, are designed to be placed in adoctor's office where space is at a premium. Like the analyzersdescribed above, a certified operator may operate these machines.

However, it is difficult to guarantee that such an operator is actuallyoperating the analyzer. In many instances, the person operating themachine may have little or no training on the analyzer. Even whentrained, the operator may not follow the various procedures required foraccurate testing of a patient blood sample.

For example, performance of a quality control check of the analyzer maybe required on a periodic basis to ensure that the analyzer is operatingcorrectly. To perform the quality control check, various samples withknown consistencies are inserted into the analyzer for analysis.However, in many instances the samples must be thoroughly mixed beforemeasurement. When the operator skips this step, the samples may becomeunusable for future quality control checks as the consistency of thesamples may change. Thus, a new sample may be required, which willnecessarily increase the cost associated with operation of the analyzer.

In other instances, an operator may attempt to measure a patient bloodsample that has been in storage. In this case, it may be necessary totreat the patient blood sample prior to measurement to ensure accuracyof measurement. For example, the patient blood sample may need to bemixed. When an operator fails to perform this procedure correctly, themeasurement may fail or give inaccurate results.

Other problems with known analyzers will become apparent upon readingthe descriptions of the various embodiments described below.

SUMMARY

In one aspect, an analyzer includes a display, measurement hardwareconfigured to perform a measurement on a sample, and a controller. Thecontroller is in communication with the display and the measurementhardware and is configured to communicate, via the display, a firstpre-analytical procedure of the sample prior to measurement of thesample. The controller is also configured to maintain the analyzer in astate associated with the first procedure for an amount of time neededfor performing the first procedure. After the time needed for performingthe first procedure has elapsed, the controller is configured tocommunicate, via the display, a second pre-analytical procedure of thesample prior to measurement of the sample.

In a second aspect, a method for performing a measurement on a sampleincludes providing display and measurement hardware configured toperform the measurement on a sample. The method also includescommunicating, via the display, a first pre-analytical procedure of thesample prior to measurement of the sample, maintaining a stateassociated with the first procedure for an amount of time needed forperforming the first procedure. After the time needed for performing thefirst procedure has elapsed, the method includes communicating, via thedisplay, a second pre-analytical procedure of the sample prior tomeasurement of the sample.

In a third aspect, a non-transitory machine-readable storage mediumincludes at least one code section that causes a machine to communicate,via a display, a first pre-analytical procedure of a sample prior tomeasurement of the sample, maintaining a state associated with the firstprocedure for an amount of time needed for performing the firstprocedure. After the time needed for performing the first procedure haselapsed, the code section causes the machine to communicate, via thedisplay, a second pre-analytical procedure of the sample prior tomeasurement of the sample.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an exemplary system diagram of a hematology analyzer andserver;

FIG. 2 is an exemplary block diagram of operations for confirmingoperator registration and training for the system of FIG. 1;

FIGS. 3A and 3B are exemplary images that may be presented on a displayof the hematology analyzer during the operations of FIG. 2;

FIG. 4 is an exemplary block diagram for performing a quality controlcheck of the hematology analyzer of FIG. 1;

FIGS. 5A and 5B are exemplary images that may be presented on a displayof the hematology analyzer during the operations of FIG. 4;

FIG. 6 is an exemplary block diagram for instructing an operator on thecorrect pre-analytical procedures of a sample;

FIGS. 7A-13A are exemplary images that may be presented on a display ofthe hematology analyzer during the operations of FIG. 6;

FIG. 14 illustrates a general computer system that may represent any ofthe computing devices referenced herein.

DETAILED DESCRIPTION

The embodiments below describe an exemplary embodiment of an analyzersystem. For example, the analyzer system may include a hematologyanalyzer configured to analyze a patient blood sample and a server incommunication with the hematology analyzer. In particular, the system isconfigured to ensure that an operator is qualified to use the analyzerand that the operator adheres to certain procedures while operating theanalyzer. In one embodiment, the analyzer system prevents an operatorfrom using an analyzer until it can be confirmed that the operator isqualified to use the analyzer. In second and third embodiments, theoperator is presented with step-by-step instructions that guide theoperator in the proper use of the analyzer.

FIG. 1 is an exemplary hematology analyzer system 100 (hereinaftersystem). The system 100 includes a hematology analyzer 105 (hereinafteranalyzer) and a server 110. The analyzer 105 may include the features ofthe analyzer of U.S. Pat. No. 6,772,650, which is hereby incorporated byreferences. For example, the analyzer 105 may include an input/displaysection 120, measurement hardware 125, and a controller 127.

The measurement hardware 128 may include a sample-setting panel 125provided on a lower front right portion of the analyzer 105. Thesample-setting panel 125 is configured to be opened and closed tofacilitate placement of one or more sample vials 130 and 132 in a samplesetting section (See FIG. 12B) that is configured to measure theconsistency of samples.

The controller 127 may correspond to an Intel®, AMD®, or PowerPC® basedmicroprocessor system or a different microprocessor system. Thecontroller 127 may include an operating system, such as a MicrosoftWindows®, Linux, Unix® based operating system or a different operatingsystem. The controller 127 may be configured to communicate with othercomputers, such as the server 110, via a network 115. The controller 127may be configured to control the operation of the analyzer 105. In thisregard, the controller 127 may be configured to generate images and tocommunicate the images to the input/display section 120. The controller127 may also be configured to cooperate with the measurement hardware125 to perform various measurements. For example, the controller 127 maybe operable to cause the measurement hardware 125 to dispense a samplesfrom sample vials 130 and 132 and dilute the samples with variousreagents to thereby and analyze constituents of the samples.

In one embodiment, two sample vials 130 and 132 are utilized to ensurethat the analyzer 105 is calibrated. During normal operation, theanalyzer 105 is utilized to determine whether constituents of a patientblood sample fall within various ranges that have upper and lowerlimits. The sample vials 130 and 132 comprise substances in knownquantities configured such than when analyzed by the analyzer 105, agiven metric should produce a result at one end or the other of a rangeassociated with the metric. For example, consistency of substances inthe first sample vial 130 may be configured to provide results atrespective lower ends of the ranges. The consistency of Substances inthe second sample vial 132 may be configured to provide results atrespective upper ends of the ranges.

The sample vials 130 and 132 are generally provided in lots, where afirst lot of sample vials contains sample vials with consistenciesconfigured to provide results at a first level (e.g., lower end of therange of measured parameters), and a second lot of sample vials containssample vials with consistencies configured to provide results at asecond level (e.g., upper end of the range of measured parameters). Eachsample vial 130 and 132 is prepared with known concentrations ofsubstances and is provided with a barcode 131 that facilitatesidentification of a given sample. The barcode 131 and concentrationinformation for each sample vial 130 and 132 is stored in a sampledatabase 135.

The sample vials 130 and 132 may be used repeatedly. For example, thesample vials 130 and 132 may be utilized on daily basis when performinga quality control check of the analyzer 105, as described below. Witheach use, some material in the sample vial 130 and 132 is depleted.Thus, there is a finite number of times in which a given sample vial 130and 132 may be utilized. In addition, the sample vials 130 and 132 mayhave an expiration date. Accordingly, the number of times for which agiven sample vial 130 and 132 is used and the expiration date for eachsample vial 130 and 132 may be stored in the sample database 135, so asto keep track of the usable life of the sample vial 130 and 132. In someimplementations, the analyzer 105 is configured to prevent use of agiven sample vial 130 and 132 when it has been used more than apredetermined number of times or passed its expiration date.

The input/display section 120 of the analyzer 105 is configured toprovide instructions to an operator of the analyzer 105 and to receiveinput from the operator. The input/display section 120 may be positionedon a front upper portion of the analyzer 105 and may correspond to atouch sensitive display that enables operator input. In otherimplementations, operator input may come by way of a keyboard (nowshown) coupled to the analyzer 105. As described below, via theinput/display section 120, the operator may be questioned as to whetherhe is registered with the analyzer 105 and whether he has completed atraining session (i.e., familiarization session). The operator may beinstructed to insert various sample vials 130 and 132 into the analyzer105 to determine whether the analyzer 105 is calibrated. The operatormay be instructed on how the sample vials 130 and 132 and/or patientblood samples are to be handled prior to insertion into thesample-setting panel 125.

The server 110 may correspond to a computer system configured tocommunicate information to many analyzers 105, and to authorize theanalyzers 105 for use. The server 110 may include a controller 129 andinput/output logic that facilitates communication of data to and from asample database 135 and an operator database 140.

The controller 129 may correspond to an Intel®, AMD®, or PowerPC® basedmicroprocessor system or a different microprocessor system. Thecontroller 129 may include an operating system, such as a MicrosoftWindows®, Linux, Unix® based operating system or a different operatingsystem. The controller 129 may be configured to communicate with othercomputers, such as the analyzer 105, via a network 115. The controller129 may be configured to control the operation of the server 110. Forexample, the controller 129 may facilitate communication between theserver 110 and the analyzer 105 via a network 115. The controller 129may be operable to cause the server 110 to authorize the analyzer 105 ona periodic basis. For example, the analyzer 105 may be configured toprevent usage every twenty-four hours. In this case, the server 110 isconfigured to reauthorize the analyzer for usage on a daily basissubject to various requirements, which are described below.

The server 110 may be in communication with the sample database 135,which stores sample information. During operations, the server 110 maybe configured to communicate the sample information to the analyzer 105when requested by the analyzer 105. The analyzer 105 may store theinformation associated with a given sample internally.

The server 110 may also be in communication with the operator database140. The operator database 140 stores information associated withoperators authorized to operate a given analyzer 105. The operatorinformation may include identifying information for each operator, suchas the operator's name or an ID assigned to the operator. The operatorinformation may also indicate a date on which the operator wasauthorized and information that identifies the analyzer 105 or analyzersfor which the operator is authorized. The operator information may alsospecify whether the operator is currently authorized to use a givenanalyzer 105.

FIG. 2 illustrates exemplary operations that may be performed by ananalyzer, such as the analyzer 105 described above or a differentanalyzer, to determine whether an operator is authorized to use theanalyzer 105. The operations in FIG. 2 are best understood withreference to FIGS. 3A and 3B. Computer instructions for executing theoperations may be stored in one or more non-transitory computer readablemedia of the analyzer 105, such as a computer memory that is incommunication with the controller 127. The instructions may be executedby the controller 127 or any of the systems or processors describedherein.

At block 200, the analyzer 105 is enabled by a pre-determined event. Forexample, the analyzer 105 is enabled by being provided with power, thepower switch of the analyzer 105 may be brought out of a standby state,and/or an operator may login to the analyzer 105.

At block 205, the analyzer 105 is connected to a network 115, such asthe Internet. In this regard, an initial screen may be displayed on theinput/display section 120 if the analyzer 105 is not connected to anInternet connection. The screen may inform an operator of the analyzer105 to connect the analyzer 105 to a network connection before allowingthe operator to proceed.

At block 210, a registration confirmation message may be displayed tothe operator. For example, the registration/familiarization image 300 ofFIG. 3A may be shown to the operator via the input/display section 120.The registration/familiarization image 300 requests the operator toconfirm whether the operator has completed registration and hascompleted a familiarization session. In some implementations, theanalyzer 105 may also ask the operator for identifying information. Forexample, before using the analyzer 105, operators may be required tofirst provide registration information, such as the operator's name,place of work, etc. The operator may be required to provide informationthat identifies the analyzer 105 the operator will utilize for testingsamples, such as a serial number. The operator may provide otherinformation. Operators may also be required to take some from oftraining on the operation of the analyzer 105, such as a class on thebasic operations of the analyzer 105 that teaches procedures for usingthe analyzer 105 (e.g., how to insert samples and the like).

At block 215, if the operator indicates that he is registered, then atblock 220, the analyzer 105 may communicate with the server 110 toconfirm whether the operator has taken a familiarization session. Forexample, the analyzer 105 may send the operator identifying informationto the server 110 via the network 115. The server 110 may then searchthe operator database 140 to locate the operator and confirm that theoperator is registered and that the operator has completed thefamiliarization session.

At block 230, if the server 110 has confirmed operator familiarization,the server 110 may communicate this fact to the analyzer 105 at block232. The analyzer 105 may then proceed with other operations at block245.

If at block 230, the server 110 determines that the operator has notbeen familiarized and/or that the operator is not registered to operatethe analyzer 105, then at block 235, the server 110 may communicate thisfact to the analyzer 105.

In response, the analyzer 105 may display an image on the input/displaysection 120 informing the operator that registration and/orfamiliarization is required, such as the image 305 of FIG. 3B.

At block 240, the analyzer 105 may be powered off. Alternatively, theoperations may repeat back to block 210.

Thus, the operations above prevent an unauthorized and/orun-familiarized operator from operating the analyzer 105. This helps toensure that when samples are analyzed, they are analyzed with correctprocedures.

FIG. 4 illustrates exemplary operations that may be performed by theanalyzer 105 when performing a quality control check of the analyzer105. Quality control checks are required to ensure that the analyzer iscalibrated. In some implementations, the analyzer 105 may be configuredto require a quality control check is performed on a periodic basis,such as 7:00 AM each morning, before allowing normal measurementprocedures to occur. The operations in FIG. 4 are best understood withreference to FIGS. 5A and 5B. Computer instructions for executing theoperations may be stored in one or more non-transitory computer readablemedia of the analyzer 105, such as a computer memory that is incommunication with the controller 127. The instructions may be executedby the controller 127 or any of the systems or processors describedherein.

At block 400, instructions for performing a control check based on alevel A sample vial 130 may be presented to the operator via theinput/display section 120. The operator may then select a level A samplevial 130 and scan a barcode 131 of the level A sample vial 130. Theoperator then inserts the level A sample vial 130 into thesample-setting panel 125. The analyzer 105 may then measure the amountof various substances in the level A sample vial 130. The measurementsare compared with known quantities of the substances associated with thespecific level A sample vial 130. As noted above, data that defines theactual quantities of the substances for each vial is stored in thesample database 135 and can be located via the barcode 131. If a givenlevel A sample vial 130 has been tested before, the actual quantitiesmay be stored locally in the analyzer 105. Otherwise, the analyzer 105communicates the barcode 131 to the server 110. The server 110 thenresponds with the actual quantities associated with the level A samplevial 130.

At block 405, the analyzer 105 determines whether the measurements arewithin an acceptable range of the known quantities of substancesassociated with the level A sample vial 130. If the measured quantitiesare out of range, then at block 410, the analyzer 105 determines whetherthis specific level A sample vial 130 has failed before.

If the level A sample vial 130 has not failed before, then at block 415,a failure count associated with the level A sample vial 130 isincremented. The failure count may be maintained within a memory of theanalyzer 105. In addition or alternatively, the failure count may becommunicated to the server 110 and stored in a record of the sampledatabase 135 that is associated with the level A sample vial 130.

At block 420, the operator is instructed to retest the failed level Asample vial 130. FIG. 5A illustrates an exemplary image 500 that may beshown to the operator via the input/display section 120 to instruct theoperator to retest the failed level A sample vial 130.

After the operator is instructed to retest the failed level A samplevial 130, the operations may repeat from block 400.

If at block 410, the failure count associated with the level A samplevial 130 is equal to one, the failure count may be incremented again. Insome implementations, a second failure renders the level A sample vial130 unusable for future quality control checks. As such, the level Asample vial 130 may be flagged as unusable. The updated failure countand/or flag may be maintained within a memory of the analyzer 105. Inaddition or alternatively, the failure count and/or flag may becommunicated to the server 110 and stored in a record of the sampledatabase 135 that is associated with the level A sample vial 130.

Following the second failure, the operator may be instructed to select anew level A sample vial 130. For example, the image 505 of FIG. 5B maybe communicated to the operator via the input/display section 120. Theoperations may then repeat from block 400.

The rational for retesting after the first failure is that in someinstances, a level A sample vial 130 may result in a failure because thelevel A sample vial 130 was not mixed properly. In this situation, thesubstances within the level A sample vial 130 may not be evenlydistributed throughout the level A sample vial 130. Heavier substanceswill tend to accumulate at the bottom of the level A sample vial 130. Aneedle through which the sample is drawn by the measurement hardware 128tends to draw the sample from near the bottom of the level A sample vial130. Under these circumstances, an increased quantity of heaviersubstances will be withdrawn, thus causing the failure. However, as aresult of the uneven distribution of the substances, the various ratiosof substances will change unevenly. In other words, the relativeconcentrations of the substances within the level A sample vial 130 willchange. This may render the level A sample vial 130 unusable for futurequality control checks. In some implementations, one failure may betolerated provided the operator subsequently mixes the level A samplevial 130 thoroughly on the second attempt. However, after a subsequentfailure, the level A sample vial 130 may be rendered unusable for futurequality control checks. The number of times a given level A sample vial130 may be allowed to fail may be greater in some instances. Forexample, the size of the level A sample vial 130 or the manner in whicha sample is withdrawn may be configured so that more than one failure istolerable.

Returning to block 405, if the level A sample vial 130 passes thequality control check, then at block 430, a level B sample vial 132 istested. The level B sample vial 132 is tested in the same manner as thelevel A sample vial 130. That is, if the level B sample vial 132 fails afirst quality control check, a failure count specifically associatedwith the level B sample vial 132 is incremented by one and the operatoris instructed to perform the quality control check a second time. If thequality control check fails a second time, the operator is instructed toselect a new level B sample vial 132 for quality control checking.

At block 435, after a level A sample vial 130 and a level B sample vial132 vial have passed the quality control checks, then a flag may be setto indicated that a further quality control check is not required for acertain period. In some implementations, the flag is reset on a periodicbasis, such as on a twenty-four hour cycle or at a specific time of day.

At block 440, the analyzer 105 is ready for normal operations. That is,an operator may begin measuring actual patient blood samples.

Thus, the operations above minimize the wasting of level A sample vials130 and level B sample vials 132 by allowing for a given sample vial tofail a specified number of times before the sample vial is flagged asbeing unusable. This in turn helps to reduce lower operating costs.

FIG. 6 illustrates exemplary operations that may be performed by theanalyzer 105 for the pre-analytical procedures of a patient sample.Pre-analytical procedures of a patient sample may be required in someinstances to ensure accurate measurement of the patient sample. Theoperations in FIG. 6 are best understood with reference to FIGS. 7A-13A.Computer instructions for executing the operations may be stored in oneor more non-transitory computer readable media of the analyzer 105, suchas a computer memory that is in communication with the controller 127.The instructions may be executed by the controller 127 or any of thesystems or processors described herein.

At block 600, the operator specifies a type of patient sample vessel tobe tested. FIG. 7A illustrates an exemplary image 700 that may be shownto the operator via the input/display section 120. In the exemplaryimage 700, the operator specifies that the blood is either in a standardtest tube or in a micro-collection tube. The standard tube may holdpatient blood that was sampled several days prior testing, whereas theblood in the micro-collection tube may have just been obtained. In thecase of a standard tube, the blood may have settled into its constituentcomponents. For example, the blood platelets may accumulate towards thebottom of the test tube. To ensure accurate measurement of the patientblood sample, the test tube must be shaken to evenly distribute theblood constituents.

After being presented with the different patient sample vessel options,the operator selects the desired vessel. A confirmation image (See FIG.7B) may be presented to the operator to confirm the desired vesselselection.

The operator may then be provided with instructions for inserting vesseladapter into the analyzer 105. For example, as illustrated in FIG. 8A,an image 800 that includes instructions along with graphical depictionsfor inserting the vessel adapter may be presented on the input/displaysection 120. Once the operator completes this procedure, the operatormay indicate that this procedure is complete.

The operator may then enter an ID associated with the patient. Forexample, as illustrated in FIG. 8B, an image 805 that includes a numerickeypad along instructions for specifying the patient ID may be presentedon the input/display section 120. Once the operator completes thisprocedure, the operator may indicate that this procedure is complete. Insome implementations, the operator may be asked to confirm the patientID (See FIG. 9A). For example, the analyzer 105 may determine that theID is new and request confirmation before generation of a record of datafor the new patient.

At block 605, the operator may be instructed to check the temperature ofthe patient blood sample. For example, as illustrated in FIG. 9B, theoperator may be presented with an image 905 via the input/displaysection 120 that includes instructions. The instructions may ask theoperator whether the patient blood sample is cold to the touch. Thetemperature of the patient blood sample may indicate whether the patientblood sample was recently acquired or whether the patient blood samplewas in storage. As noted above, a recently acquired patient blood samplemay still be mixed relatively thoroughly, which will result in moreaccurate testing of the blood. On the other hand, a patient blood samplethat was stored may have separated into its constituent components. Inthis case, some additional processing may be required before testing thepatient blood sample, as described below.

If at block 610, the patient blood sample is cold to the touch, then atblock 615, the operator may be presented with instructions for warmingthe patient blood sample. For example, as illustrated in FIG. 10A, animage 1000 with instructions for warming the patient blood sample may bepresented to the operator via the input/display section 120. Theinstructions may indicate that the operator is to warm the patient bloodsample between his fingers until the patient blood sample is no longercold to the touch.

At block 620, a graphical button 1010 for specifying that the warming iscomplete is presented to the operator. The graphical button 1010 mayinitially display a numeric value corresponding to a timer countdownvalue in seconds. The initial value may correspond to a pre-determinedtime necessary for performing the current procedure. For example, thepre-determined time necessary for warming the patient blood sample maybe thirty seconds. The initial value may be a time longer than thepre-determined time necessary for warming the patient blood sample.

The value shown on the graphical button 1010 may slowly decrement untilreaching zero. While counting down, the graphical button 1010 may beunresponsive to operator input, thus preventing the operator fromquickly skipping ahead to the final steps for testing the patient bloodsample. This in turn increases the likelihood that the operator willactually warm the patient blood sample as instructed.

Once the countdown is completed, the text “complete” may be displayed onthe graphical button 1010, as illustrated in FIG. 10B. The operator maythen select the graphical button 1010 to proceed.

At block 625, the operator may be presented with instructions for mixingthe patient blood sample. For example, as illustrated in FIG. 11A, animage 1100 with instructions for starting a mixing process may bepresented to the operator via the input/display section 120. Theinstructions may ask the operator whether to continue on to a mixingprocess.

If the operator continues, the operator may be presented withinstructions for mixing the patient blood sample. For example, asillustrated in FIG. 11B, an image 1105 with instructions for mixing thepatient blood sample may be presented to the operator via theinput/display section 120. A graphical depiction 1110 may indicate themanner in which the operator is to mix the patient blood sample.

At block 630, a graphical button 1115 for specifying that the mixing iscomplete is presented to the operator. The graphical button 1115 mayinitially display a numeric value corresponding to a timer countdownvalue in seconds. The initial value may correspond to a pre-determinedtime necessary for performing the current procedure. For example, thepre-determined time necessary for mixing the patient blood sample may befifteen seconds.

The value presented on the graphical button 1115 may slowly decrementuntil reaching zero. While counting down, the graphical button 1115 maybe unresponsive to operator input, thus preventing the operator fromquickly skipping ahead to the final steps for testing the patient bloodsample. This in turn increases the likelihood that the operator willactually mix the patient blood sample as instructed.

At block 635, the operator may be presented with instructions forinserting the patient blood sample in the sample-setting panel 125 ofthe analyzer 105. For example, as illustrated in FIG. 12B, an image 1205with instructions for inserting the sample tube and a graphicaldepiction of the same may be presented to the operator via theinput/display section 120.

At block 640, the operator may be presented with an image 1300 (FIG.13A) that displays a progress bar 1305. The image may be automaticallygenerated after the operator closes the sample-setting panel 125. Theprogress bar 1305 is configured to represent to the operator therelative progress of the testing.

At block 645, the progress bar 1305 may indicate that the analysis iscomplete. Once complete, an analysis report may be communicated to theoperator. For example, a printer (not shown) attached to the analyzer105 may print the results of the analysis. In addition or alternatively,the analysis report may be communicated to others electronically. Forexample, the analysis may be emailed to a doctor, hospital, and thelike.

Returning to block 610, if the patient blood sample is already warm tothe touch, the operations at blocks 615 through 630 may be skipped, andthe operations may continue from block 635.

Thus, the operations above help ensure accurate testing of a patientblood sample by instructing an operator on pre-analytical procedures ofthe patient blood sample. The operations help to ensure that theoperator performs certain pre-analytical procedures for a pre-determinedamount of time.

FIG. 14 illustrates a general computer system 1400, which may representportions of the analyzer 105, such as the controller 127 or the sever orany other computing devices referenced herein. The computer system 1400may include a set of instructions 1445 that may be executed to cause thecomputer system 1400 to perform any one or more of the methods orcomputer-based functions disclosed herein. The computer system 1400 mayoperate as a stand-alone device or may be connected, e.g., using anetwork, to other computer systems or peripheral devices.

In a networked deployment, the computer system 1400 may operate in thecapacity of a server or as a client-operator computer in a server-clientoperator network environment, or as a peer computer system in apeer-to-peer (or distributed) network environment. The computer system1400 may also be implemented as or incorporated into various devices,such as a personal computer or a mobile device, capable of executing aset of instructions 1445 (sequential or otherwise) that specify actionsto be taken by that machine. Further, each of the systems described mayinclude any collection of sub-systems that individually or jointlyexecute a set, or multiple sets, of instructions to perform one or morecomputer functions.

The computer system 1400 may include one or more memory devices 1410 ona bus for communicating information, such as the sample database 135(FIG. 1) and/or operator database 140 (FIG. 1). In addition, codeoperable to cause the computer system to perform any of the acts oroperations described herein may be stored in the memory 1410. The memory1410 may be a random-access memory, read-only memory, programmablememory, hard disk drive or any other type of memory or storage device.

The computer system 1400 may include a display 1430, such as a liquidcrystal display (LCD), a cathode ray tube (CRT), or any other displaysuitable for conveying information. The display 1430 may act as aninterface for the operator to see the functioning of the processor 1405,or specifically as an interface with the software stored in the memory1410 or in the drive unit 1415.

Additionally, the computer system 1400 may include an input device 1425,such as a keyboard or mouse, configured to allow an operator to interactwith any of the components of system 1400.

The computer system 1400 may also include a disk or optical drive unit1415, such as the high-latency storage 110 (FIG. 1). The disk drive unit1415 may include a computer-readable medium 1440 in which one or moresets of instructions 1445, e.g. software, can be embedded. Further, theinstructions 1445 may perform one or more of the operations as describedherein. The instructions 1445 may reside completely, or at leastpartially, within the memory 1410 and/or within the processor 1405during execution by the computer system 1400. The memory 1410 and theprocessor 1405 also may include computer-readable media as discussedabove.

The computer system 1400 may include a communication interface 1435 thatenables communications via a network 1450. The network 1450 may includewired networks, wireless networks, or combinations thereof. Thecommunication interface 1435 network may enable communications via anynumber of communication standards, such as 802.11, 802.12, 802.20,WiMax, cellular telephone standards, or other communication standards.

Accordingly, the method and system may be realized in hardware,software, or a combination of hardware and software. The method andsystem may be realized in a centralized fashion in at least one computersystem or in a distributed fashion where different elements are spreadacross several interconnected computer systems. Any kind of computersystem or other apparatus adapted for carrying out the methods describedherein is suited. A typical combination of hardware and software may bea general-purpose computer system with a computer program that, whenbeing loaded and executed, controls the computer system such that itcarries out the methods described herein.

The method and system may also be embedded in a computer programproduct, which includes all the features enabling the implementation ofthe operations described herein and which, when loaded in a computersystem, is able to carry out these operations. Computer program in thepresent context means any expression, in any language, code or notation,of a set of instructions intended to cause a system having aninformation processing capability to perform a particular function,either directly or after either or both of the following: a) conversionto another language, code or notation; b) reproduction in a differentmaterial form.

While the method and system has been described with reference to certainembodiments, it will be understood by those skilled in the art thatvarious changes may be made and equivalents may be substituted withoutdeparting from the scope. In addition, many modifications may be made toadapt a particular situation or material to the teachings withoutdeparting from its scope. Therefore, it is intended that the presentmethod and system not be limited to the particular embodiment disclosed,but that the method and system include all embodiments falling withinthe scope of the appended claims.

1. An analyzer for performing a measurement on a sample, wherein anoperator of the analyzer follows a plurality of procedures prior tomeasurement of the sample, the analyzer comprising: a display;measurement hardware configured to perform the measurement on thesample; and a controller in communication with the display and themeasurement hardware configured to: continuously communicate, via thedisplay, a first pre-analytical procedure of the sample prior tomeasurement of the sample for an amount of time needed for performingthe first pre-analytical procedure; and after the time needed forperforming the first pre-analytical procedure has elapsed, communicate,via the display, a second pre-analytical procedure of the sample priorto measurement of the sample.
 2. The analyzer according to claim 1,wherein the controller is configured to communicate the secondpre-analytical procedure automatically after the time needed forperforming the first procedure has elapsed.
 3. The analyzer according toclaim 1, wherein the controller is configured to wait until an operatorindicates a readiness to proceed before communicating the secondpre-analytical procedure.
 4. The analyzer according to claim 3, whereinin the controller is configured to generate, on the display, a graphicalbutton and enable the graphical button for operator input after the timeneeded for performing the first pre-analytical procedure has elapsed. 5.The analyzer according to claim 4, wherein the controller is configuredto display on the button an indication of the elapsed time or theremaining time.
 6. The analyzer according to claim 1, wherein the firstpre-analytical procedure comprises warming of the sample.
 7. Theanalyzer according to claim 1, wherein the second pre-analyticalprocedure comprises mixing of the sample.
 8. A method for performing ameasurement on a sample, wherein an operator follows a plurality ofprocedures prior to measurement of the sample, the method comprising:providing a display; providing measurement hardware configured toperform the measurement on the sample; and controlling by at least onecontroller the display to continuously communicate, via the display, afirst pre-analytical procedure of the sample prior to measurement of thesample for an amount of time needed for performing the firstpre-analytical procedure; after the time needed for performing the firstpre-analytical procedure has elapsed, communicate, via the display, asecond pre-analytical procedure of the sample prior to measurement ofthe sample.
 9. The method according to claim 8, further comprisingcommunicating the second pre-analytical procedure automatically afterthe time needed for performing the first pre-analytical procedure haselapsed.
 10. The method according to claim 8, further comprising waitinguntil an operator indicates a readiness to proceed before communicatingthe second pre-analytical procedure.
 11. The method according to claim10, further comprising generating, on the display, a graphical buttonand enable the graphical button for operator input after the time neededfor performing the first procedure has elapsed.
 12. The method accordingto claim 11, further comprising displaying on the button an indicationof the elapsed time or the remaining time.
 13. The method according toclaim 8, wherein the first pre-analytical procedure comprises warming ofthe sample.
 14. The method according to claim 13, wherein the secondpre-analytical procedure comprises mixing of the sample.
 15. Anon-transitory machine-readable storage medium having stored thereon acomputer program comprising at least one code section for performing ameasurement on a sample, wherein an operator follows a plurality ofprocedures prior to measurement of the sample, wherein the at least onecode section is executable by a machine and the machine is incommunication with a display and measurement hardware configured toperform a measurement on a sample, and wherein the at least one codesection causes the machine to perform acts of: continuouslycommunicating, via the display, a first pre-analytical procedure of thesample prior to measurement of the sample for an amount of time neededfor performing the first pre-analytical procedure; and after the timeneeded for performing the first pre-analytical procedure has elapsed,communicating, via the display, a second pre-analytical procedure thesample prior to measurement of the sample.
 16. The non-transitorymachine-readable according to claim 15, wherein the at least one codesection is executable by the machine for causing the machine tocommunicate the second pre-analytical procedure automatically after thetime needed for performing the first procedure has elapsed.
 17. Thenon-transitory machine-readable according to claim 15, wherein the atleast one code section is executable by the machine for causing themachine to wait until an operator indicates a readiness to proceedbefore communicating the second pre-analytical procedure.
 18. Thenon-transitory machine-readable according to claim 17, wherein the atleast one code section is executable by the machine for causing themachine to generate, on the display, a graphical button and enable thegraphical button for operator input after the time needed for performingthe first pre-analytical procedure has elapsed.
 19. The non-transitorymachine-readable according to claim 18, wherein the at least one codesection is executable by the machine for causing the machine to displayon the button an indication of the elapsed time or the remaining time.20. The non-transitory machine-readable according to claim 15, whereinthe first pre-analytical procedure comprises warming of the sample. 21.The non-transitory machine-readable according to claim 20, wherein thesecond pre-analytical procedure comprises mixing of the sample.